Amplitude controlled sine wave oscillator

ABSTRACT

An amplitude control circuit of the invention includes a vector composition circuit (18) for composing a cosine-wave signal (e3) from a sine-wave signal (e1) and a control signal generation circuit (20) for providing a control signal (e4) from the sine- and cosine-wave signals (e1, e3) which the control signal (e4) has substantially no ripples. DC level of the control signal (e4) is varied proportional to the amplitude of the sine-wave signal (e1) regardless of the frequency of the sine-wave signal (e1). The amplitude of an amplification control circuit (12) is controlled by the control signal (e4) so that the amplitude of the oscillation output signal (e1) derived from the oscillation circuit (16) is constant.

RELEVANT ART

This invention relates to an amplitude control circuit for stabilizing the output signal amplitude of a sine-wave signal oscillator.

BACKGROUND OF THE INVENTION

For a sine-wave oscillator, especially an oscillator within a frequency range of a few Hz to a few hundreds KHz, Wien-bridge type or Sulzer type CR oscillator is generally used. Means for stabilizing the output signal amplitude often used are set forth as follows:

(a) By using a resistance variable element with Joule heat, such as a glass-tube enclosed type thermistor or a tungsten lamp.

(b) By using a resistance variable element with a control signal, such as an FET or a photo-cell type optical coupler.

The amplitude stabilizing means of the former (a) is popularly employed because of its simple construction. By means of (a), however, a low harmonics-distortion sine-wave signal below a few tens Hz is hardly obtained. Because the inner resistance of the amplitude stabilizing element is modulated by the amplitude change, not by the RMS (Root Mean Square) of the oscillation output signal amplitude. To solve this problem, an extremely large heat capacity is required for the amplitude stabilizing element. But a large heat capacity of the stabilizing element makes a trackability deteriorated, which the trackability means a response speed or a traceability for the average-variation of oscillation output amplitude. The deterioration of trackability will provide a fluctuation of the output amplitude, which is the so-called "hunting". The hunting phenomenon appears whenever the oscillation frequency is changed, and practically, this is very uncomfortable phenomenon. As mentioned above, matters to obtain a low harmonics-distortion and a little hunting at a low frequency range are contrary to each other.

The amplitude stabilizing means of the latter (b) is somewhat more complicated than the former (a) in consideration of the constructions or configurations. However, the amplitude stabilizing means of (b) is also often used. Because an amplitude stabilizing element for the (b) means is usually cheap device and hardly affected by surrounding temperature or mechanical vibration. In this means, the inner resistance of the amplitude stabilizing element is controlled by a control voltage or a control current. Suppose that we apply a source-drain resistance of FET to the amplitude stabilizing element. In this case the inner resistance of the FET is controlled by a gate-source voltage. Usually an average or peak level of rectified oscillation output signal is employed in the control voltage. Ripple components of the rectified oscillation output signal are eliminated through an eliminator or filter circuit.

In the case of the amplitude stabilizing means (b), when a low harmonics-distortion of oscillation output signal at low frequency range is required, a time constant of the filter circuit should also be set at large. Because an amplitude of ripple included in the control signal is enlarged with decrease of oscillation frequency, if the time constant is small. This ripple modulates the inner resistance of the amplitude stabilizing elements and makes the distortion factor of the oscillation output signal worsened. On the contrary a large time constant is applied to the filter circuit for lowering the distortion factor of oscillation output signal, said hunting phenomenon is in the forefront. Accordingly, even by the amplitude stabilizing means of (b), lowering the harmonics-distortion and avoiding the hunting phenomenon are the anti-requirement.

However, the art with the stabilizing means (b), which can solve the anti-requirement above-mentioned, i.e. provide a low harmonics-distortion and a little hunting, has been developed. To the best of inventor's knowledge, the most recent publication is "Transistor Technics" of October, 1978 published by CQ publishing company in Japan. In pages 283 to 300 of this publication a trial manufacture description of a sine-wave oscillator which may be solve said anti-requirement is disclosed. In the oscillator, a peak value of the oscillation output is sampled and held every cycle. When obtaining a control voltage by such a sample/hold circuit, after the holding state, ripples do not get mixed with the control voltage. However, in the case where the oscillation frequency is extremely low, I feel that the control voltage might be varied during sampling so as to distort the oscillation output. Accordingly, when an extremely low-frequency below a few Hz and low-distortion sine-wave signal is required without influence of said hunting phenomenon, the construction of the sample/hold circuit should, probably, be further devised or improved.

SUMMARY OF THE INVENTION

The object of this invention is to provide an amplitude control circuit suitable for a sine-wave oscillator, which can satisfy the anti-requirement of lowering a distortion factor and decreasing a hunting phenomenon.

To attain above object, an amplitude control circuit according to this invention includes an oscillator circuit which comprises:

an amplifier means to provide an oscillation output signal;

an amplification control means disposed in a first feedback loop of the amplifier means to control the amplification degree thereof; and

an oscillation frequency setting means disposed in a second feedback loop to determine the frequency of the oscillation frequency output signal;

wherein the amplitude control circuit further includes:

a vector composition means for composing a first phase-shifted signal and a second phase-shifted signal, which the first phase-shifted signal has a phase difference from the oscillation output signal and is derived from the oscillation frequency setting means, and which the second phase-shifted signal has a predetermined phase difference from the oscillation output signal;

a control signal generation means to provide a control signal corresponding to an amplitude of the oscillation output signal in accordance with the second phase-shifted signal and the oscillation output signal, so that the amplitude of the oscillation output signal is kept constant.

According to the amplitude control circuit including above constructions, the control signal corresponding to the amplitude of the oscillation output signal, but substantially being independent of the oscillation frequency, can be obtained.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram showing a basic configuration of sine-wave oscillator which includes an amplitude control circuit according to the invention;

FIG. 2 is a circuit diagram showing an embodiment of FIG. 1;

FIGS. 3A and 3B are vector diagrams useful for explaining a vector-composition by the vector composition circuit 18 of FIG. 1;

FIGS. 4A to 4C show waveforms of sine-waves ±e1a, cosine-waves ±e3a and a control signal e4a indicated in the circuit of FIG. 2;

FIG. 5 is a graph showing an example of a gate voltage-drain current characteristic of P channel FETs 28 to 34 shown in FIG. 2;

FIG. 6 is a modification of the oscillation circuit 16 shown in FIG. 2;

FIG. 7 is a block diagram showing a modification of the square-function composing circuit included in the control signal generation circuit 20 of FIG. 2;

FIG. 8 is an embodied circuit of the square-function circuit 72, 76 of FIG. 7;

FIGS. 9 to 11 show modifications of the oscillation circuit 16 of FIG. 2;

FIG. 12 is a block diagram which shows modified configuration of the vector composition circuit 18 and the control signal generation circuit 20 of FIG. 1;

FIG. 13 shows a vector diagram of signals produced in the blocks of FIG. 12;

FIG. 14 shows a waveform diagram indicating how a control signal e4 is obtained at the condition "n=3" of FIG. 12 configuration;

FIG. 15 is an embodied circuit of FIG. 12 configuration; and

FIG. 16 is a block diagram in which the amplitude control circuit of FIG. 1 is applied to an automatic level control circuit.

DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

Now the preferred embodiments of the invention will be described below. In the description same or like portions are indicated by same or like reference numerals to avoid redundant explanation.

FIG. 1 shows a basic configuration of sine-wave oscillator which includes an amplitude control circuit according to the invention. An output signal e1 of an amplifier circuit 10 is input to an amplification control circuit 12. The signal e1 is positively (or negatively) fed back to a first input of the amplifier 10 through the control circuit 12. Also the signal e1 is negatively (or positively) fed back to a second input of the amplifier 10 via an oscillation frequency setting circuit 14. The circuit components 10, 12 and 14 constitute a conventional oscillation circuit 16. Suppose that the signals supplied to the first and second input of the amplifier 10 are, e.g., positive and negative feedback signals, respectively. In this case, the oscillation circuit 16 forms Sulzer type (Bridged T type) oscillator. On the contrary signals supplied to the first and second inputs are negative and positive feedback signals, the oscillation circuit 16 forms Wien-bridge type oscillator.

The signal e1 is supplied to a first input of a vector composition circuit 18. A second input of the composition circuit 18 is supplied with a phase-shifted signal e2 which is derived from the setting circuit 14. When Sulzer type or Wien-bridge type is applied to the setting circuit 14, a phase-shift amount about 45° of the signal e2 as against the signal e1 can be obtained. The signals e1 and e2 are converted into a signal e3 whose phase is shifted by 90° from the signal e1, by means of the composition circuit 18. For example, when the signal e1 is a sine-wave, the signal e3 is a cosine-wave. Also the signal e1 is supplied to a first input of a control signal generation circuit 20. A second input of the generation circuit 20 is supplied with the signal e3.

The control signal generation circuit 20 synthesizes a control signal e4 which includes a DC component proportioning to the sum of squared signals e1 and e3. That is, the DC component of the signal e4 can be explained by a function with parameter of e1² +e3². Suppose that the signals e1 and e3 are defined as below:

    e1=E sin ωt                                          (1)

    e2=E cos ωt                                          (2)

wherein E denotes an amplitude (corresponding to the peak value) of each signals e1 and e3, ω an angular frequency and t a time. Then the signal e4 is expressed as ##EQU1## wherein k denotes a proportion constant which is a property of the generation circuit 20. Clearly anticipated from the equation (3), the signal e4 is independent of the angular frequency ω of the oscillation output signal e1. The signal e4 only contains information proportional to the square of amplitude E of the signal e1. By the signal e4 the transfer function of the control circuit 12 is controlled.

FIG. 2 is a detail circuit diagram of the basic configuration shown in FIG. 1. The inventor believes that this circuit configuration is a best mode at the time the application is filed.

An output of an amplifier 10 is connected via a resistor R12₂ to a non-inverted input of the amplifier 10. The non-inverted input is grounded through a resistance R12₁ of an impedance controlled element 12₁. For the element 12₁ a photo-coupler combining LED and CdS cell is preferably applied. The element 12₁ and the resistor R12₂ form the amplification control circuit 12. An inverted input of the amplifier 10 is connected to the output thereof, through a resistor R14₁. A series circuit of capacitors C14₁ and C14₂ is parallel connected to the resistor R14₁. The connection point of capacitors C14₁ and C14₂ is connected via a resistor R14₂ to an inverted input of an amplifier 22. The resistors R14₁, R14₂ and the capacitors C14₁, C14₂ form the oscillation frequency setting circuit 14 of Bridged T type. The amplifier 10, impedance controlled element 12₁, resistors R12₂, R14₁, R14₂ and capacitors C14₁, C14₂ constitute the oscillation circuit 16.

The inverted input of the amplifier 22 is connected to an output thereof via a resistor R18₁. A non-inverted input of the amplifier 22 is grounded through a resistor R18₂. The resistor R18₂ is provided for an off-set balancing. The output of the amplifier 22 is connected to the output of the amplifier 10 through a series circuit of resistors R18₃ and R18₄. The amplifier 22 and the resistors R18₁ to R18₄ form the vector composition circuit 18. The inverted input of the amplifier 22 is in the state of "imaginary ground". That is, the junction point of the resistors R14₂ and R18₁ is equivalently grounded. At the connection point of the capacitors C14₁ and C14₂ in the oscillation frequency setting circuit 14, the phase-shifted signal e2 appears. The phase-shifted signal e2 is a sine-wave voltage signal having a phase difference φ from the sine-wave oscillation output signal e1 of the oscillation circuit 16. The signal e2 is converted to a current signal i2 corresponding to e2/R14₂ and input to the vector composition circuit 18. The current signal i₂ is converted into a phase-shifted signal e2a by the amplifier 22. The phase-shifted signal e2a is antiphased from the signal e2. An amplitude of the signal e2₁ can be varied by the resistor R18₁. The phase-shifted signal e2a and the oscillation output signal e1 are added by an adder circuit being formed of the resistors R18₃ and R18₄. By this addition a phase-shifted signal e3 whose phase is differenced by 90° from the signal e1, is obtained.

Reference should be made to FIG. 3A. This figure illustrates how the composition of the phase-shifted signal e3 is performed in the vector composition circuit 18. Now we suppose that the phase-shifted signal e2 is phase-delayed by φ from the oscillation output signal e1. To invert the phase of the signal e2 and amplify its amplitude by A₁, the phase-shifted signal e2a is obtained. By vector-summing the signal e2a and the signal e1 a phase-shifted signal e3 is composed. The phase difference between the signal e1 and the signal e3 can be set at 90° by adjusting the amplitude rate A₁. Namely, the vector composition circuit 18 composes a cosine-wave signal from a sine-wave signal. A 90° phase-shifted signal A₂ e3 whose amplitude is equal to the oscillation output signal e1, is obtained from amplifying the signal e3 by A₂.

Reference should return to FIG. 2 the output of the amplifier 10 is connected to an inverted input of an amplifier 24, through a series circuit of resistors R20₁ and R20₂. The inverted input of the amplifier 24 is coupled with its output via a resistor R20₃. A non-inverted input of the amplifier 24 is grounded by way of a resistor R20₄ for off-set balancing. The junction point of the resistors R18₃ and R18₄ is connected to an inverted input of an amplifier 26, through a series circuit of resistors R20₅ and R20₆. The inverted input of the amplifier 26 is coupled with its output via a resistor R20₇. A non-inverted input of the amplifier 26 is grounded by way of a resistor R20₈.

In the circuit configuration above-mentioned, suppose that R20₂ =R20₃ and R20₆ =R20₇. In this case, when a signal appeared at the junction point of the resistors R20₁ and R20₂ is deemed as e1_(a), a signal appeared at the output of the amplifier 24 is -e1a. Similarly, a signal at the junction point of the resistors R20₅ and R20₆ as e3a, a signal at the output of the amplifier 26 as -e3a. The signal e1a is in-phase with the oscillation output signal e1 and the signal e3a is in-phase with the phase-shifted signal e3. Accordingly a phase difference of 90° is presented between the signals e1a and e3a. Amplitudes of the signals e1a and e3a can be adjusted by the resistors R20₁ and R20₅, respectively. The amplitudes of signals e1a and e3a can therefore be set to equal each other. The phase relations of the signals e1a, -e1a and the signals e3a, -e3a are respectively shown in FIGS. 4A and 4B.

Reference should be made to FIG. 2, again. The junction point of the resistors R20₁ and R20₂ is connected to the gate of a P channel MOS FET 28. The output of the amplifier 24 is connected to the gate of a P channel MOS FET 30. Similarly, the junction point of R20₅ and R20₆ and the output of the amplifier 26 are connected to the gates of P channel MOS FETs 32 and 34, respectively. In this circuit an enhancement type is used for the FETs 28 to 34. However, any type of device may be used whose characteristic of drain current I_(D) can substantially be represented by a square-function of its gate-source voltage V_(GS). For example, a depletion type may be applied to FETs 28 to 34. The chief reason for applying an enhancement type FETs in FIG. 2 is that the circuit configuration can easily be simplified. FIG. 5 shows a typical I_(D) -V_(GS) characteristic of P channel FET. In this figure, a curve "A" indicates an enhancement type and -V_(TH) designates its threshold voltage. A curve "B" indicates a depletion type and +V_(p) designates its pinch-off voltage. Generally the curves "A", "B" can be represent by a square-function with good accuracy.

In FIG. 2, the drains of FETs 28 and 30 are connected through a resistor R20₉ to a negative power source -V_(E). The drains of FETs 32 and 34 are connected to the power source -V_(E) via a resistor R20₁₀. The resistors R20₉ and R20₁₀ is used for over-current limiter. Each substrate and source of FETs 28 and 30 is connected to the emitter of an NPN transistor 36. Also, each substrate and source of FETs 32 and 34 is connected to the emitter of an NPN transistor 38. The bases of the transistors 36 and 38 are connected to the base and collector of an NPN transistor 40. The emitter of the transistor 40 is grounded through a resistor R20₁₁. The collector of the transistor 40 is connected to a positive power source +V_(C) via a resistor R20₁₂. The diode-connected transistor 40 is provided for temperature-compensation of the base-emitter threshold voltages V_(BE) of the transistors 36 and 38. Gate bias voltages V_(SG) for the FETs 28 to 34 can be adjusted by the resistor R20₁₂. In this circuit, "dual" type, in which electrical characteristics of packed pellets are matched, are suitable for the FETs 28 and 30, also for the FETs 32 and 34.

The collectors of the transistors 36 and 38 are connected through a resistor R20₁₃ to the cathode of an LED or light emission device which is coupled with the impedance controlled element 12₁. The anode of the LED is connected to the positive power source +V_(C). The collectors of the transistors 36 and 38 are grounded, via a capacitor C20₁. The capacitor C20₁ is provided for decreasing remaining ripples included in a control current I₄ or in a control voltage e4 which is applied to the amplification control circuit 12. If the I_(D) -V_(GS) characteristics of the FETs 28 to 34 may completely be regarded as a square function, the control current I₄ does not involve the ripples. However, where the I_(D) -V_(GS) characteristics do not meet at the square function the current I₄ includes some ripples. Frequency components of the ripple are higher harmonics over second order of the oscillation output signal e1's frequency. Moreover the amplitude of the ripple component is extremely small as compared with the DC level of the control current I₄. The time constant may therefore be small, which is formed of the capacitor C20₁ and the corrector circuit impedance of the transistors 36 and 38. When the accuracy of the square-function characteristics are adequate, or there is no requirement to the oscillation output signal e1 whose distortion factor should be extremely low, the capacitor C20₁ may be deleted.

The amplifiers 24 and 26, FETs 28 to 34, transistors 36 to 40, resistors R20₁ to R20₁₃ and the capacitor C20₁ are constituting the control signal generation circuit 20.

The composing operation of the control current I₄, i.e. the control signal e4 as set forth in equation (3), can be explained as described below. This explanation will be made by referring FIGS. 4 and 5. Suppose that, in FIG. 2, the source-potentials of FETs 28 to 34 are adjusted at the threshold voltage +V_(TH). This means that the gate voltage -V_(GS) to the sources of FETs 28, 30 or FETs 32, 34 are -V_(TH) at the time of zero-amplitude of the signal e1a or e3a. In this case, the FET 28 is cutoff during the positive half period of the signal e1a. While the negative half period of the signal e1a, a current i₂₈ proportional to e1a² is flowing into the source-drain path of FET 28. Similarly, only the negative half period of the signal -e1a or the positive half period of the signal e1a, a current i₃₀ proportional to (-e1a)² is flowing into the FET 30. Then a current i₂₈ +i₃₀ proportional to e1a² flows in the collector circuit of the transistor 36 along the whole phase.

In the same way, a current i₃₂ proportional to e3a² and a current i₃₄ to (-e3a)² are flowing into the FETs 32 and 34, respectively. Then a current i₃₂ +i₃₄ proportional to e3a² flows in the collector circuit of the transistor 38 along the whole phase. The sum of the currents i₂₈, i₃₀, i₃₂ and i₃₄ provides the control current I₄. A collector voltage e4a of the transistors 36 and 38 corresponding to the control current I₄ is a DC signal including some ripples, as shown in FIG. 4C. The ripples will appear when said square-function characteristics can not precisely be obtained. The level of the DC signal is proportional to the square of the amplitude of oscillation output signal e1, but has no relation to the oscillation frequency. The control current I₄ also has a waveform as shown in FIG. 4C. By using such control current I₄, a CR oscillator with low-distortion and low-hunting can be provided.

By applying the amplitude control circuit of this invention, a stable oscillation output signal can be obtained irrespective of its oscillation frequency. Accordingly, an extreme low frequency sine-wave signal, which has only been put to practical use by a function generator, can be obtained by a conventional Sulzer type or Wien-bridge type oscillator circuit with this invention.

Hitherto a function generator is widely used for an extreme low frequency band sine-wave oscillator. In the function generator a sine-wave is composed from a triangle-wave by functional conversion of f(x)=sin x/x. Accurate conversion of this function is difficult, technically. It is therefore hard to obtain a low distortion sine-wave from a triangle-wave. Further, a sine-wave obtained from this functional conversion is attended with a large distortion including much higher harmonics of odd number order. On the contrary, by the configuration of FIG. 2, an extremely low frequency sine-wave signal e1 with low distortion factor can be obtained.

FIG. 6 shows a modification of oscillation circuit 16 applicable to this invention. In this circuit a bootstrap type positive feedback circuit is applied to the oscillation frequency setting circuit 14. This positive feedback circuit is one modification of another Japanese Patent Application "BAND REJECTION CIRCUIT" which is made by the same inventor. This application is Japanese Patent Application No. 145981/76 filed on Dec. 4, 1976 and is amended on Aug. 23, 1977.

A positive feedback circuit of the amplifier 10 or the amplification control circuit 12 has the same configuration of FIG. 2. On the other hand the negative feedback circuit is constructed as below. The output of the amplifier 10 is connected to a non-inverted input of an amplifier 14₁, via a series circuit of resistors R14₁ and R14₂. The junction point of the resistors R14₁ and R14₂ is connected through a capacitor C14₁ to an output of the amplifier 14₁. The output of the amplifier 14₁ is connected through a resistor R14₄ to an inverted input thereof. The inverted input of the amplifier 14₁ is grounded via a resistor R14₅. The non-inverted input of the amplifier 14₁ is connected through a capacitor C14₂ to the non-inverted input of the amplifier 10. The non-inverted input of the amplifier 10 is grounded via a resistor R14₃.

In this circuit, when an amplitude A₁₄ of the amplifier 14₁ is "1", or R14₄ /R14₅ =0, the oscillation frequency can be varied by the capacitors C14₁ and/or C14₂. It is undesirable to use the resistors R14₁ and/or R14₂ for varying the oscillation frequency, when A₁₄ =1. If the resistor R14₁ or R14₂ is varied, the negative feedback amount of the amplifier 10 at the oscillation frequency is also varied in accordance with the variance of the resistor. This makes the amplitude of the oscillation output signal e1 changed. In the extreme case, the output signal e1 may be clipped or the oscillation be stopped. However, when the resistors R14₁, R14₂ and R14₃ is so varied as to hold the relation "(R14₁ +R14₂)/R14₃ =constant", no problem will occur.

Suppose that the following relation is held.

    A.sub.14 =R14.sub.4 /R14.sub.5 +1=C14.sub.2 /C14.sub.1 +1  (4)

Arranging the relation (4),

    R14.sub.4 C14.sub.1 =R14.sub.5 C14.sub.2                   (5)

is obtained.

When the relation (4) or (5) is held, if the oscillation frequency is varied by R14₁, no amplitude variation is occurred in the oscillation output signal e1. In the case where A₁₄ =2 and C14₁ =C14₂, for example, the relation (4) or (5) is satisfied. In this case, the transfer function at the oscillation frequency from the output of the amplifier 10 to the non-inverted input thereof, is independent of the resistor R14₁. Thus, the oscillation frequency may be varied by changing the resistor R14₁. Detail description relating to the theoretical analysis of the relations mentioned above is set forth on the amended specification of said Japanese Patent Application No. 145981/76.

In the oscillation circuit 16 of FIG. 6, there is an advantage that a device (resistor or capacitor) for varying the oscillation frequency may be single. This means that such a circuit is particularly suitable to constitute a voltage controlled oscillator (VCO). On the other hand, in an oscillation circuit of Sulzer or Wien-bridge type, at least a two-ganged or more ganged type variable resistor or variable capacitor (variable condenser) is required for varying the oscillation frequency, and when such a ganged device includes a gang-error the amplitude of the oscillation output e1 is liable to vary with varying the oscillation frequency.

FIG. 7 shows a modification of the square function composition circuit in the control signal generation circuit 20. In the case of FIG. 2 a square function characteristic between the gate-source voltage V_(GS) and the drain current I_(D) of FETs 28˜34 is applied. Further, a full-wave rectification for the signals e1 and e3 is realized by the FETs 28 to 34 such that these FETs are cut-off during the positive half period of ±e1 and ±e3. Such a full-wave rectification and square function composition of the FETs 28 to 34 may be realized by a general configuration as shown in FIG. 7. In this configuration the signal e1 is converted to, for example, a pulsation signal e1a of positive period of sine-wave by a full-wave rectifier 70. The signal e1a is converted to a squared signal e1a² by a square function circuit 72. Similarly the signal e3 is converted to a squared signal e3a² through a full-wave rectifier 74 and a square function circuit 76. The squared signals e1a² and e3a² is added by an adder 78. Then the adder 78 provides the squared signal e4a=e1a² +e3a².

The full-wave rectifiers 70, 74 and the square function circuit 72, 76 and the adder 78 may be conventional ones. For the rectifier 70 or 74 a linear rectifier circuit, which comprises an operational amplifier whose negative feedback loop includes a rectifying diode or a rectifying transistor, is suitable. For the square function circuit 72 or 76, following circuit means is suitable.

(a) By means of a tangential approximation using diodes.

(b) By means of a combination of log-compressor, doubler amplifier and exponential function circuit. For example, an input signal e1 is converted through the log-compressor to log e1. This log e1 is doubled by the doubler amplifier and is converted to 2 log e1=log e1². This log e1² is converted to exp (log e1²)=e1², via the exponential function circuit.

(c) By means of an application of √ type (root or radical type) voltage-current characteristic which appears in a low voltage range of a drain current and drain-source voltage property of an FET. A circuit example of such means is shown in FIG. 8.

An output of an amplifier 72₁ is connected to the drain of an N channel depletion type FET 72₂. The source of the FET 72₂ is connected to an inverted input of the amplifier 72₁. The inverted input is grounded via a resistor R72₁. Connected between the source and gate of the FET is a gate-bias voltage source 72₃. The curve of the drain current and source-drain voltage of the FET 72₂ can be varied by changing the voltage of the source 72₃. When a positive potential signal e1a with a given amplitude is input to a non-inverted input of the amplifier 72₁, a signal nearly proportional to e1a² is obtained from the output of the amplifier 72₁.

FIGS. 9 through 12 show modifications of the oscillation circuit 16 shown in FIG. 2. In FIG. 9 a resistor R12₂ within an impedance controlled element 12₁ included in the amplification control circuit 12 is connected between the non-inverted input and output of an amplifier 10. When the amplitude of the oscillation output signal el is increased, a current I₄ supplied to a lamp included in the element 12₁ is decreased. In this figure the decrease of the current I₄ is indicated by -I₄ which marked with a negative sign. With decrease of the current I₄, the resistance value of the resistor R12₂ is increased, then the amplitude of the signal el is decreased. Further, for the oscillation frequency setting circuit 14, a capacitor C14₁ is used as a bridging element, and the supplement of said oscillation circuit current i₂ is carried out through a capacitor C14₂.

In FIG. 10, a Wien-bridge type oscillation circuit is employed for the oscillation circuit 16. The output of an amplifier 10 is connected through a resistor R12₂ to the inverted input thereof. The inverted input of the amplifier 10 is grounded, via a resistor R12₃ and the drain-source path of an N channel FET 12₁. For this FET 12₁ a depletion type is considered. When an enhancement type or P channel type FET is used for the FET 12₁, a biasing method or a polarity of the control signal e4a should be changed. Connected between the drain-gate path of the FET 12₁ is a resistor R12₄. The resistor R12₄ is employed in a negative feedback to compensate the non-linearity of the inner resistance (R12₁) of the FET 12₁. By the negative feedback operation, drain voltage-drain current characteristic of the FET 12₁ displays a non-saturation curve which is so-called "triode characteristic". When such a negative feedback is used, substituting a bipolar transistor for the FET 12₁ may be done. Even though by employing a bipolar transistor 12₁, said triode characteristic can apparently be obtained. To the gate of the FET 12₁ a control signal e4a is applied through a resistor R12₅. In FIG. 10 the control signal e4a is makred with negative sign. This negative sign denotes that the amplitude increment of the oscillation output signal e1 makes the potential of the control signal e4a lowered. That is, the negative control signal -e4a is proportional to the amplitude of the oscillation output signal e1.

The output of the amplifier 10 is connected to the non-inverted input thereof, via a series circuit of a capacitor C14₁ and a resistor R14₁. The non-inverted input of the amplifier 10 is grounded through a parallel circuit of a resistor R14₂ and a capacitor C14₂. The junction point of the resistor R14₁ and the capacitor C14₁ is connected to a non-inverted input of an amplifier 14₂. An inverted input of the amplifier 14₂ is connected to an output thereof. The phase-shifted signal e2 is derived from the output of the amplifier 14₂. The amplifier 14₂ is merely provided for an impedance converter. In the oscillation circuit 16 of FIG. 10, the phase-shifted direction of the signal e2 is opposite to that of FIG. 2. In this case the composition of a 90° phase-shifted signal e3 is performed as shown in FIG. 3B.

FIG. 11 shows a modification of the oscillation circuit 16 shown in FIG. 10. The output of the amplifier 10 is connected to the non-inverted input thereof, through a series circuit of a resistor R14₁ and a capacitor C14₁. The non-inverted input of the amplifier 10 is grounded, via a parallel circuit of a resistor R14₂ and a capacitor C14₂. The output of the amplifier 10 is connected through a resistor R12₂ to the inverted input thereof. The inverted input of the amplifier 10 is grounded via a resistor R12₃. The output of the amplifier 10 is connected through a resistor R12₆ to an inverted input of an amplifier 14₃. The inverted input of the amplifier 14₃ is connected to an output thereof via a resistor R12₇. A non-inverted input of the amplifier 14₃ is grounded.

Connected between the inverted input of amplifier 10 and the output of amplifier 14₃ is the drain-source path of an enhancement type P channel MOS·FET 12₁. The substrate of the FET 12₁ is grounded. The gate of the FET 12₁ is connected through a resistor R12₄ to the drain (or source) thereof. The gate is also connected to the source (or drain) via a resistor R12₈. To the gate of the FET 12₁ the control signal e4a is supplied through a resistor R12₅. The gate is connected through a resistor R12₉ to a negative power source -V_(E) for biasing the FET 12₁. The phase-shifted signal e2 is derived from the junction point of the resistor R14₁ and the capacitor C14₁.

In the oscillation circuit 16 of FIG. 11, suppose that the drain-source structure of the FET 12₁ is symmetrical with respect to the gate and R12₄ =R12₈, and that the amplitude of a signal e10 at the inverted input of the amplifier 10 is same as that of a signal e14 at the output of the amplifier 14₃ by adjusting the value of a resistance ratio R12₇ /R12₆. Then, the drain and source of the FET 12₁ are applied with the signals e10 and e14 which have the same amplitude and antiphase relation with each other with respect to the substrate potential. Thus, the FET 12₁ is driven in a condition of "Push-Pull". Such configuration is well fitted for amplitude-controlling of a large amplitude signal. The resistors R12₄ and R12₈ is used for compensating the non-linearity of inner resistance of the FET 12₁. However, an oscillation output signal e1 with relatively low distortion can be obtained without using the resistors R12₄ and R12₈ when the amplitude of a signal applied to the FET 12₁ is small. By fine-adjusting the amount of a resistance ratio R12₇ /R12₆, a minimum point of distortion of the oscillation output signal e1 can be attained.

FIG. 12 shows a modification of the basic configuration of FIG. 1. In FIG. 1, a signal e2=sin (ωt-φ) is converted to e3=cos ωt by the vector composition circuit 18, and a control signal e4=e1² +e3², which does substantially not include ripples, is obtained from the control signal generation circuit 20. On the contrary, in FIG. 12, "n" kinds of phase-shifted signals e3n are composed by "n" blocks of vector composition circuits 18n. The control signal e4 is obtained from summing the absolute peak values of these signals e3n. Thus, FIG. 12 shows a configuration embodying the following equation: ##EQU2## In the equation (6), when i=0, or e3₀ =E sin (ωt-φ₀), this directly corresponds to the oscillation output. The bracket "[ ]" denotes the peak absolute value.

The oscillation output signal e1 is applied to an absolute peak value detector 21₀ and the first input of vector composition circuits 18₁ to 18n. The circuits 18₁ to 18n compose phase-shifted signals e3₁ to e3n based on the signals e1 and e2. Each of the composition circuits 18₁ to 18n may has the same configuration as that of the composition circuit 18 shown in FIG. 2. Signals e3₁ to e3n composed by the circuits 18₁ to 18n, respectively, are input to absolute peak value detectors 21₁ to 21n. The signals e3₁ to e3n are converted to absolute peak value signals |e1| and |e3₁ | to |e3n|, respectively. These signals are added by an adder 23.

FIG. 13 shows an example of vector diagram wherein "n=3" is applied to the equation (6). In this example, phase differences of the signals e1, e3₁, e3₂ and e3₃ are 45°. If the phase-shift amount of the phase-shifted signal e2 is originally 45°, the vector composition at the time of n=3 can easily be accomplished.

FIG. 14 shows an envelope of the control signal e4 which is composed in the case of n=3. Ripples of the peak of the signals e1, e3₁, e3₂ and e3₃ applied to the adder 23 are small. The time constants of charge-discharge circuits of the detectors 21₀ to 21₃ may therefore be relatively small.

FIG. 15 shows a sine-wave oscillator which is embodied based on the block configurations of FIGS. 1 and 12. By the circuit configuration of FIG. 15, the signals e1, e3₁, e3₂ and e3₃ as shown in the vector diagram of FIG. 13 can be obtained.

The output of an amplifier 10 is connected to the non-inverted and inverted inputs thereof, via resistors R12₂ and R14₁. The non-inverted input of the amplifier 10 is grounded through a resistor R12₃ and through the drain-source path of a depletion type N channel FET 12₁. Connected between the gate and drain of the FET 12₁ is a resistor R12₄. For biasing the FET 12₁ the gate thereof is connected through a resistor R12₉ to a negative power source -V_(E). To the resistor R14₁ a series circuit of capacitors C14₁ and C14₂ is parallel connected. The junction point of the capacitors C14₁ and C14₂ is connected through a resistor R14₂ to the inverted input of an amplifier 22. The non-inverted input of the amplifier 22 is grounded and the inverted input and output thereof are coupled with each other via a resistor R18₁. The output of the amplifier 22 is coupled with the output of the amplifier 10, via a series circuit of resistors R18₃ and R18₄. The oscillation circuit 16 having such configuration is substantially the same as the oscillation circuit 16 shown in FIG. 2. Difference between these oscillation circuits are merely the difference of the device, i.e. used for the impedance controlled element 12₁ is a photo-coupler or an FET.

The junction point of the resistors R18₃ and R18₄ is connected to a non-inverted input of an amplifier 18₂₀. An output of the amplifier 18₂₀ is connected through a resistor R18₂₁ to an inverted input thereof. The inverted input of the amplifier 18₂₀ is grounded via a resistor R18₂₀. Applied to the non-inverted input of the amplifier 18₂₀ is a phase-shifted signal e3 whose phase is advanced by 90° from the oscillation output signal e1 which is obtained from the output of the amplifier 10. The signal e3 is converted to a signal e3₂, whose amplitude is same as that of the signal e1, by amplifying A₂ through the amplifier 18₂₀. The phase of the signal e3₂ is advanced by 90° from that of the signal e1. The amplification factor A₂ can be adjusted by the resistor R18₂₁.

The output of the amplifier 10 and the output of the amplifier 18₂₀ are connected to a non-inverted input of an amplifier 18₁₀ through a resistor R18₁₀ and a resistor R18₁₁, respectively. The non-inverted input of the amplifier 18₁₀ is grounded via a resistor R18₁₂. An inverted input of the amplifier 18₁₀ is connected to an output thereof, via a resistor R18_(12a). The inverted input of the amplifier 18₁₀ is grounded through a resistor R18_(12b). The composition of the signals e1 and e3₂ is performed at the junction point of the resistors R18₁₀ and R18₁₁. The amplitude of the composed signal e1+e3₂ can be adjusted by the resistor R18₁₂. Suppose that the voltage dividing ratio of the resistors R18₁₀, R18₁₁ and R18₁₂ is 1/√2 and R18_(12a) =R18_(12b). In this situation a signal e3₁ derived from the output of the amplifier 18₁₀ has the same amplitude as that of the signal e1 and is phase-advanced by 45° from the signal e1.

The output of the amplifier 10 is connected through a resistor R18₆ to an inverted input of an amplifier 18₀₀. Connected between the inverted input and output of the amplifier 18₀₀ is a resistor R18₇. The non-inverted input of the amplifier 18₀₀ is grounded. In the case where R18₆ =R18₇, obtained from the output of the amplifier 18₀₀ is a signal -e1 which has the same amplitude as that of the signal e1 and has an anti-phase relation with the signal e1. The output of the amplifier 18₂₀ and the output of the amplifier 18₀₀ are coupled with a non-inverted input of an amplifier 18₃₀ through a resistor R18₃₀ and a resistor R18₃₁, respectively. The non-inverted input of the amplifier 18₃₀ is grounded via a resistor R18₃₂. An inverted input of the amplifier 18₃₀ is connected to an output thereof, via a resistor R18_(32a). The inverted input of the amplifier 18₃₀ is grounded through a resistor R18_(32b). Composition of the signal e3₂ and the signal -e1 is carried out at the junction point of the resistors R18₃₀ and R18₃₁. The amplitude of the composed signal e3₂ -e1 can be adjusted by the resistor R18₃₂. A signal e3₃ derived from the output of the amplifier 18₃₀ having the same amplitude as that of the signal e1 is phase-advanced by 135° from the signal e1.

The output of the amplifier 10 is connected through a resistor R18₅ to the base of an NPN transistor 21₁₁ and the base of a PNP transistor 21₁₂. The output of the amplifier 18₁₀ is connected through a resistor R18₁₃ to the base of an NPN transistor 21₁₃ and the base of a PNP transistor 21₁₄. The output of the amplifier 18₂₀ is connected to the bases of NPN transistor 21₁₅ and PNP transistor 21₁₆, via a resistor R18₂₃. The output of the amplifier 18₃₀ is connected to the bases of NPN transistor 21₁₇ and PNP transistor 21₁₈, via a resistor R18₃₃. The collectors of the transistors 21₁₁, 21₁₃, 21₁₅ and 21₁₇ are connected to a positive power source +V_(C). The collectors of the transistors 21₁₂, 21₁₄, 21₁₆ and 21₁₈ are connected to a negative power source -V_(E). The emitters of the transistors 21₁₁, 21₁₃, 21₁₅ and 21₁₇ are grounded via a parallel circuit of a capacitor C21₁ and a resistor R21₁. The emitters of the transistors 21₁₂, 21₁₄, 21₁₆ and 21₁₈ are grounded through a parallel circuit of a capacitor C21₂ and a resistor R21₂. The transistors 21₁₁ to 21₁₈, capacitors C21₁ and C21₂, and resistors R21₁ and R21₂ constitute the absolute peak value detectors 21₀ to 21₃. In this configuration the rectifying function between the base-emitter paths of the transistors 21₁₁ to 21₁₈ are applied.

In the case where the base-emitter path of bipolar transistor is applied for a signal rectification as mentioned above, the response speed for an amplitude control of the oscillation output signal e1 is fast. Because, it can be enlarged an amount of charges per unit time, which charges are supplied to the capacitors C21₁ and C21₂, by the current-amplification function of the transistors 21₁₁ to 21₁₈. That is, if we consider the emitter output impedances of the transistors 21₁₁ to 21₁₈ are Re, the capacitors C21₁ and C21₂ are charged with time constants C21₁ Re and C21₂ Re, respectively. While, discharge time constants of these CR circuits are C21₁ R21₁ and C21₂ R21₂. By such circuit configuration of these CR charge/discharge circuits, a fast response speed and a large discharge time constant can be realized, simultaneously. Derived from the outputs of these CR charge/discharge circuits, or the emitters of the transistors 21₁₁ and 21₁₂, are peak potential +E and -E of the signals e1, e3₁, e3₂ and e3₃.

The emitter of the transistor 21₁₁ is connected to a non-inverted input of an amplifier 23₁. An output of the amplifier 23₁ is connected to an inverted input thereof. The emitter of the transistor 21₁₂ is connected to a non-inverted input of an amplifier 23₂. An output of the amplifier 23₂ is connected to an inverted input thereof. The output of the amplifier 23₂ is connected through a resistor R23₁ to an inverted input of an amplifier 23₃. A non-inverted input of the amplifier 23₃ is grounded. An output of the amplifier 23₃ is connected to the inverted input thereof via a resistor R23₂. When R23₁ =R23₂, the amplifier 23₃ constitutes an inverter with a transfer function of "-1". The outputs of the amplifiers 23₃ and 23₁ are coupled through a series circuit of resistors R23₃ and R23₄. The junction point of the resistors R23₃ and R23₄ is connected to the gate of an FET 12₁ through a resistor R12₅. The junction point of the resistors R23₃ and R23₄ provides the control signal e4. The amplifier 23₁ to 23₃ and the resistors R23₁ to R23₄ constitute the adder 23.

The minimum ripple point of the control signal e4 can be obtained by adjusting each of the resistors R18₁, R18₁₂, R18₂₁, R18₃₂ and R23₂.

Although, a phase-shifting oscillation circuit, which includes cacade-connected CR integrators or CR differentiators of 2-stage or more stage, may be applied for the oscillation circuit 16.

FIG. 16 shows a basic configuration of an ALC (Automatic Level Control) circuit or a volume expander circuit, which is an application of this invention. A phase shifter 140 may be conventional one. In the case where the FIG. 16 configuration is embodied the same configuration as the circuit of FIG. 2, a phase shift amount of the shifter 140 is selected to 90°. When the circuit configuration of FIG. 15 is applied, a preferable phase shift amount of the shifter 140 is 45°. When the FIG. 16 configuration is applied for an ALC circuit, a transfer function G=e₀ /e_(i) of the amplitude controlled circuit is small as the amplitude of the input signal e_(i) is large. On the other hand, this configuration is applied for a volume expander circuit, the transfer function G is large as the amplitude of the signal e_(i) is large. In the amplitude controlled circuit of FIG. 16, the control signal e4 does almost not include ripples even though the operation speed of the control is set to fast. From this, the transfer function G is almost not modulated by the ripple component of the control signal e4.

APPLICABLE FIELD OF THE INVENTION

Application of am amplitude control circuit of the invention is suitable for a CR (or LR, LC) type oscillator with an oscillation frequency range below about 1 MHz. Particularly, by using a circuit configuration as shown in FIG. 2, it should be watched that a low-distortion sine-wave generator within extremely low frequency range of about 1 Hz or less can be obtained.

Further, a circuit configuration (18+20) for controlling the amplitude of oscillator according to the invention can be applicable to an ALC (Automatic Level Control) circuit or AGC (Automatic Gain Control) circuit. Thus, to compose a signal whose phase is shifted from the input signal by a conventional phase shifter, the vector composition circuit 18 and the control signal generation circuit 20 shown in FIG. 2 or FIG. 15 may directly be applied to an ALC or AGC circuit. In this case a configuration corresponding to the amplification control circuit 12 corresponds to an attenuator which is level controlled automatically. 

What is claimed is:
 1. An amplitude controlled sine wave oscillator comprising:amplifier means (10) having first and second feedback loops, for providing an oscillation signal (e1); amplification control means (12) provided in said first feedback loop, for controlling the gain of said amplifier means (10); frequency set means (14) provided in said second feedback loop, for setting a frequency of said oscillation signal (e1) and for providing a first phase-shifted signal (e2) which has a given phase difference from said oscillation signal (e1), the amount of said given phase difference being larger than 0° and less than 180°; vector composition means (18) coupled to said amplifier means (10) and to said frequency set means (14) for vector-composing from said oscillation signal (e1) and first phase-shifted signal (e2) a second phase-shifted signal (e3) having a 90° phase difference from said oscillation signal (e1); and control means (20) coupled to said amplifier means (10) and to said vector composition means (18) for squaring said oscillation signal (e1) and said second phase-shifted signal (e3), and combining these two squared signals (e1², e3²) to generate a control signal (e4a) which is used for controlling the gain of said amplifier means (10); characterized in that said control signal means (20) includes filter means (C20₁, R20₁₃) for reducing ripple components of said control signal (e4a) to provide a ripple-less signal (I4), said ripple components containing higher harmonic frequencies of the oscillation frequency of said oscillation signal, and said ripple-less signal (I4) being applied as gain control data to said amplification control means (12) so that the amplitude of said oscillation signal (e1) is kept constant.
 2. An amplitude controlled sine wave oscillator comprising:amplifier means (10) having first and second feedback loops, for providing an oscillation signal (e1); amplification control means (12) provided in said first feedback loop, for controlling the gain of said amplifier means (10); frequency set means (14) provided in said second feedback loop, for setting a frequency of said oscillation signal (e1) and for providing a phase-shifted signal (e2) which has a given phase difference from said oscillation signal (e1), the amount of said given phase difference being larger than 0° and less than 180°; vector composition means (18) coupled to said amplifier means (10) and to said frequency set means (14) for vector-composing from said oscillation signal (e1) and phase-shifted signal (e2) a plurality of polyphase signals (e3₁ -e3₃) each having a given phase difference from said oscillation signal (e1); and control signal means (21+23) coupled to said amplification control means (12) and to said vector composition means (18) for combining said polyphase signals (e3₁ --e3₃) to generate a control signal (e4) which is used for controlling the gain of said amplifier means (10); characterized in that the wave forms of said polyphase signals (e3₁ -e3₃) are overlapped with one another so that ripples involved in the envelope of said polyphase signals (e3₁ -e3₃) decrease, and that said control signal means (21+23) includes filter means (R21₁, R21₂, C21₁, C21₂) for further reducing ripple components of said control signal (e4) to provide a ripple-less signal (I4), said ripple components containing higher harmonic frequencies of the oscillation frequency of said oscillation signal, and said ripple-less signal (I4) being applied as gain control data to said amplification control means (12) so that the amplitude of said oscillation signal (e1) is kept constant.
 3. An amplitude controlled sine wave oscillator comprising:first means (10) having first and second feedback loops, for generating an output signal (e1); second means (12) provided in said first feedback loop for varying the feedback amount of said first feedback loop; third means (14) provided in said second feedback loop for determining a frequency of said output signal (e1) and generating a first signal (e2) whose phase is shifted from said output signal (e1) by a given amount; fourth means (18) coupled to said first and third means (10,14) for composing a second signal (e3) from said output signal (e1) and said first signal (e2), said second signal (e3) being phase-shifted from said output signal (e1) by a predetermined amount; fifth means (20) coupled to said first and fourth means (10, 18) for composing a third signal (e4a) from signals (e1a,-e1a,e3a,-e3a) corresponding to said output signal (e1) and said second signal (e3), said third signal (e4a) containing higher harmonic frequencies of the oscillation frequency of said output signal and having a DC potential corresponding to the amplitude of said output signal (e1); and sixth means (C20₁,R20₁₃) coupled to said second and fifth means (12,20) for reducing said higher harmonic frequencies of said third signal (e4a) and supplying said second means (12) with a control signal (I4) to vary the feedback amount of said first feedback loop so that the amplitude of said output signal (e1) is kept constant.
 4. The oscillator of claim 3 wherein the predetermined amount of phase-shift of said second signal (e3) from said output signal (c₁) is substantially 90°; andsaid fifth means (20) includes means (28-40) coupled to said first and fourth means (10,18) for squaring each of said signals (e1a,-e1a,e3a,-e3a) corresponding to said output and second signals (e1,e3) and combining the squared signals (e1a²,e3a²) to generate said third signal (e4a).
 5. The oscillator of claim 3 wherein said fourth means (18) includes:means (18₁ -18_(n) in FIG. 12 or 18₁₀,18₂₀, 18₃₀, etc. in FIG. 15) responsive to said output and second signals (e1,e3), for generating a plurality of polyphase signals (e3₁ -e3₃) corresponding to said output and second signals (e1,e3) in a manner that the phase of one of said polyphase signals (e3₁ -e3₃) is different from the phase of the other of said polyphase signals; and said fifth means (20) includes: means (21₁ -21_(n) in FIG. 12 or 21₁₃ -21₁₈,23₁,23₂ in FIG. 15) coupled to said generating means (18₁₀ -18₃₀, etc.) for detecting a peak level of said polyphase signals (e3₁ -e3₃) to provide detected signals (+E,-E) corresponding to said third signal (e4 or e4a).
 6. The oscillator of claim 3 wherein said first means (10) includes an amplifier (10) having an inverted input terminal (-) and an output terminal, andsaid third means (14) includes a bridged T circuit which includes: a series circuit of first and second impedance elements (C14₁,C14₂) coupled between the inverted input terminal (-) and the output terminal of said amplifier (10); a third impedance element (R14₁) coupled in parallel to the series circuit of said first and second impedance elements (C14₁,C14₂); and a fourth impedance element (R14₂) coupled between a junction of said first and second impedance elements (C14₁,C14₂) and a terminal with substantially zero AC potential, a signal (e2) appearing at the junction of said first and second impedance elements (C14₁,C14₂) being utilized as said first signal (e2).
 7. The oscillator of claim 3 wherein said first means (10) includes an amplifier (10) having a noninverted input terminal (+) and an output terminal, andsaid third means (14) includes a Wien-bridge circuit which includes: a series circuit of first and second impedance elements (R14₁,C14₁) coupled between the noninverted input terminal (+) and the output terminal of said amplifier (10); and a parallel circuit of third and fourth impedance elements (R14₂,C14_(2l) ) coupled between the noninverted input terminal (+) of said amplifier (10) and a terminal with a lower AC potential than that at the noninverted input terminal (+) of said amplifier (10), a signal (e2) appearing at the junction of said first and second impedance elements (R14₁, C14₁) being utilized as said first signal (e2).
 8. The oscillator of claim 3 wherein said first means (10) includes a first amplifier (10) having a noninverted input terminal (+) and an output terminal, andsaid third means (14) includes: a series circuit of a first resistor (R14₁), a second resistor (R14₂) and a first capacitor (C14₂), coupled between the noninverted input terminal (+) and the output terminal of said first amplifier (10); a third resistor (R14₃) coupled between the noninverted input terminal (+) of said first amplifier (10) and a terminal with a lower AC potential than that at the noninverted input terminal (+) of said first amplifier (10); a second amplifier (14₁) with a given gain having a noninverted input terminal (+) coupled to the junction of said second resistor and said first capacitor, and an output terminal;and a second capacitor (C14₁) coupled between a junction of said first and second resistors (R14₁, R14₂) and the output terminal of said second amplifier (14₁), a signal (e2) appearing at the output terminal of said second amplifier (14₁) corresponding to said first signal (e2).
 9. The oscillator of claim 8 wherein the given gain of said second amplifier (14₁) is substantially "1", and any of said first and second capacitors (C14₁,C14₂) is used for varying the oscillation frequency of said output signal (e1).
 10. The oscillator of claim 8 wherein the given gain of said second amplifier (14₁) is substantially "1", and said first, second and third resistors (R14₁ -R14₃) are used for varying the oscillation frequency of said output signal (e1), provided that the ratio of: ##EQU3## ((R14₁ +R14₂)/R14₃) is kept constant.
 11. The oscillator of claim 8 wherein the given gain of said second amplifier (14₁) is substantially the same as the sum (C14₂ /C₁₄ 1+1) of a ratio (C14₂ /C14₁) of the capacitance of said first capacitor (C14₂) to the capacitance of said second capacitor (C14₁) and a constant value "1", and the first resistor (R14₁) is used for varying the oscillation frequency of said output signal (e1).
 12. The oscillator of claim 3 wherein said fifth means (20) includes:a first circuit (R20₁ -R20₄,24) responsive to said output signal (e1) for generating a fourth signal (e1a) and a fifth signal (-e1a) which has an antiphase relation with said fourth signal (e1a); a second circuit (R20₅ -R20₈,26) responsive to said second signal (e3) for generating a sixth signal (e3a) and a seventh signal (-e3a) which has an antiphase relation with said sixth signal (e3a); a first FET (28) having a gate which receives said fourth signal (e1a) and a drain which is supplied with a given potential (-VE); a second FET (30) having a gate which receives said fifth signal (-e1a) and a drain which is supplied with a given potential (-VE); a third FET (32) having a gate which receives said sixth signal (e3a) and a drain which is supplied with a given potential (-VE); a fourth FET (34) having a gate which receives said seventh signal (-e3a) and a drain which is supplied with a given potential (-VE); a third circuit (36) coupled to sources of said first and second FETs (28,30) for combining source currents of said first and second FETs (28,30) to supply said sixth means (C20₁) with a first current which corresponds to the squared value (e1a²) of said fourth and fifth signals (e1a,-e1a); and a fourth circuit (38) coupled to sources of said third and fourth FETs (32,34) for combining source currents of said third and fourth FETs (32,34) to supply said sixth means (C20₁) with a second current which corresponds to the squared value (e3a²) of said sixth and seventh signals (e3a,-e3a), the sum of said first and second currents of said third and fourth circuits (36,38) corresponding to said third signal (e4a). 